230 research outputs found

    `Thermodynamics' of Minimal Surfaces and Entropic Origin of Gravity

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    Deformations of minimal surfaces lying in constant time slices in static space-times are studied. An exact and universal formula for a change of the area of a minimal surface under shifts of nearby point-like particles is found. It allows one to introduce a local temperature on the surface and represent variations of its area in a thermodynamical form by assuming that the entropy in the Planck units equals the quarter of the area. These results provide a strong support to a recent hypothesis that gravity has an entropic origin, the minimal surfaces being a sort of holographic screens. The gravitational entropy also acquires a definite physical meaning related to quantum entanglement of fundamental degrees of freedom across the screen.Comment: 12 pages, 1 figur

    Radial geodesics as a microscopic origin of black hole entropy. I: Confined under the Schwarzschild horizon

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    Causal radial geodesics with a positive interval in the Schwarzschild metric include a subset of trajectories completely confined under a horizon, which compose a thermal statistical ensemble with the Hawking-Gibbons temperature. The Bekenstein--Hawking entropy is given by an action at corresponding geodesics of particles with a summed mass equal to that of black hole in the limit of large mass.Comment: 16 pages, 12 eps-figures, iopart class, tought experiment (p.7) adde

    Heat-kernel Coefficients and Spectra of the Vector Laplacians on Spherical Domains with Conical Singularities

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    The spherical domains SβdS^d_\beta with conical singularities are a convenient arena for studying the properties of tensor Laplacians on arbitrary manifolds with such a kind of singular points. In this paper the vector Laplacian on SβdS^d_\beta is considered and its spectrum is calculated exactly for any dimension dd. This enables one to find the Schwinger-DeWitt coefficients of this operator by using the residues of the ζ\zeta-function. In particular, the second coefficient, defining the conformal anomaly, is explicitly calculated on SβdS^d_\beta and its generalization to arbitrary manifolds is found. As an application of this result, the standard renormalization of the one-loop effective action of gauge fields is demonstrated to be sufficient to remove the ultraviolet divergences up to the first order in the conical deficit angle.Comment: plain LaTeX, 23 pp., revised version, a misprint in expressions (1.8) and (4.38) of the second heat coefficient for the vector Laplacian is corrected. No other change

    Thermodynamics, Euclidean Gravity and Kaluza-Klein Reduction

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    The aim of this paper is to find out a correspondence between one-loop effective action WEW_E defined by means of path integral in Euclidean gravity and the free energy FF obtained by summation over the modes. The analysis is given for quantum fields on stationary space-times of a general form. For such problems a convenient procedure of a "Wick rotation" from Euclidean to Lorentzian theory becomes quite non-trivial implying transition from one real section of a complexified space-time manifold to another. We formulate conditions under which FF and WEW_E can be connected and establish an explicit relation of these functionals. Our results are based on the Kaluza-Klein method which enables one to reduce the problem on a stationary space-time to equivalent problem on a static space-time in the presence of a gauge connection. As a by-product, we discover relation between the asymptotic heat-kernel coefficients of elliptic operators on a DD dimensional stationary space-times and the heat-kernel coefficients of a D1D-1 dimensional elliptic operators with an Abelian gauge connection.Comment: latex file, 22 page
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